High Temperature Vapors: Science and Technology |
From inside the book
Results 1-3 of 49
Page 123
... flow , CT 580 → 1200 Jeffes and Marples ( 1972 ) Si ( s ) + SiCl , Ti ( s ) + 2TiCl , Te ( s ) + I2 = Tel2 440 Mo ( s ) + 2MoO3 = 3M0O2 1600 → T1a Al ( s ) Al2S3 = Al2S Al ( s ) + AICI , = AICI = 2SiCl2 = 3TiCl2 1300 < 1000 flow 1000600 ...
... flow , CT 580 → 1200 Jeffes and Marples ( 1972 ) Si ( s ) + SiCl , Ti ( s ) + 2TiCl , Te ( s ) + I2 = Tel2 440 Mo ( s ) + 2MoO3 = 3M0O2 1600 → T1a Al ( s ) Al2S3 = Al2S Al ( s ) + AICI , = AICI = 2SiCl2 = 3TiCl2 1300 < 1000 flow 1000600 ...
Page 231
... flow velocity . This allows a stationary reaction zone to persist and the burning velocity S , is related to the volume flow V of unburnt gas and the flame front area Af by V = Su X Aƒ . Nonstationary , or turbulent , flames usually ...
... flow velocity . This allows a stationary reaction zone to persist and the burning velocity S , is related to the volume flow V of unburnt gas and the flame front area Af by V = Su X Aƒ . Nonstationary , or turbulent , flames usually ...
Page 233
... flow per unit area per unit time , is determined by the concen- tration , i.e. , species per unit volume , and also by the diffusion velocity , i.e. , species flow per unit time . In a flow system , such as a flame , the net reaction ...
... flow per unit area per unit time , is determined by the concen- tration , i.e. , species per unit volume , and also by the diffusion velocity , i.e. , species flow per unit time . In a flow system , such as a flame , the net reaction ...
Contents
Appendix Major Literature Sources for High Temperature Chemistry | 36 |
Synergistic Reactions | 58 |
Appendix Some Additional Recent Literature on High Temperature GasSolid | 89 |
Copyright | |
10 other sections not shown
Other editions - View all
Common terms and phrases
addition apparent application atmosphere atoms basic calculated Chapter Chem chemical chemistry chloride combustion complex components composition concentration considered constant containing corrosion dependence deposition determined diffusion discussion dissociation effect electron elements emission energy equilibrium et al evidence example experimental factor flame formation fuel gases given greater H-atom H₂O halide halogen heat Hence high temperature hydroxide important increase indicated inhibition interaction interest involving ions kcal mol-¹ kinetic known lead less limited mass materials mechanism metal molecular observed obtained occur oxide partial particularly phase Phys plasma possible practical presence present pressure problems production radical reaction reaction zone reactor recent reduced region relatively rocket shown similar solid species stability studies suggested surface Table techniques thermal thermodynamic tion transport usually values vapor vapor-phase various volatile York